A rotor includes: a plurality of first magnetic pole members that are disposed such that first end portions and second end portions are respectively coupled magnetically and mechanically to a first magnetic end plate and to a second magnetic end plate and so as to be separated from a magnetic intermediate plate magnetically; a plurality of second magnetic pole members that are disposed such that intermediate portions are coupled magnetically and mechanically to the magnetic intermediate plate and so as to be separated from each of the magnetic end plates magnetically; a plurality of permanent magnets that are disposed between the first and second magnetic pole members in a circumferential direction; and a nonmagnetic holding body for separating the first magnetic pole members magnetically from the magnetic intermediate plate, and for separating the second magnetic pole members magnetically from the magnetic end plates.
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1. A lundell rotary machine comprising:
a tubular stator that has stator magnetic poles;
a rotor that has rotor magnetic poles that face the stator magnetic poles and that can be coupled magnetically, and that is rotated relative to the stator inside the stator; and
a pair of magnetic field coils that are disposed radially inside the rotor magnetic poles, and that generate magnetic flux inside the stator and inside the rotor, wherein the rotor includes:
a pair of first and second magnetic end plates that are disposed so as to be separated from each other in an axial direction;
a magnetic intermediate plate that is disposed between the pair of magnetic end plates in the axial direction, and that is also disposed between the pair of field coils in the axial direction;
a plurality of first magnetic pole members that extend axially, and that are disposed so as to be spaced apart circumferentially from each other such that first end portions and second end portions are respectively coupled magnetically and mechanically to the first magnetic end plate and to the second magnetic end plate and so as to be separated from the magnetic intermediate plate magnetically;
a plurality of second magnetic pole members that extend axially, that are disposed so as to be spaced apart circumferentially from each other such that intermediate portions are coupled magnetically and mechanically to the magnetic intermediate plate and so as to be separated from each of the magnetic end plates magnetically, that are respectively inserted between the first magnetic pole members, and that constitute the rotor magnetic poles together with the first magnetic pole members;
a plurality of permanent magnets that are respectively disposed between the first magnetic pole members and the second magnetic pole members in a circumferential direction such that first end portions extend to the first magnetic end plate and second end portions extend to the second magnetic end plate; and
a nonmagnetic holding body for separating the first magnetic pole members magnetically from the magnetic intermediate plate, and for separating the second magnetic pole members magnetically from the magnetic end plates.
2. The lundell rotary machine according to
3. The lundell rotary machine according to
4. The lundell rotary machine according to
the first magnetic pole members and the second magnetic pole members are each supported by a dovetail groove that is formed in the axial direction on an outer circumference of the holding body; and
the permanent magnets are supported by the first magnetic pole members and the second magnetic pole members.
5. The lundell rotary machine according to
6. The lundell rotary machine according to
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The present invention relates to a Lundell rotary machine.
Conventionally, in order to enable increased output, alternators have been proposed that include: a tandem rotor in which two core segments are joined to each other so as to line up axially and in which a field coil is disposed separately inside each of the core segments; and a stator that surrounds the rotor (see Patent Literature 1, for example).
[Patent Literature 1]
Japanese Patent Laid-Open No. HEI 6-22518 (Gazette)
However, among portions of the stator that face the rotor, because magnetic flux does not interlink in portions that face a boundary between each of the core segments, alternator output is reduced.
The present invention aims to solve the above problems and an object of the present invention is to provide a Lundell rotary machine that enables increases in efficiency and increases in output.
In order to achieve the above object, according to one aspect of the present invention, there is provided a Lundell rotary machine including: a tubular stator that has stator magnetic poles; a rotor that has rotor magnetic poles that face the stator magnetic poles and that can be coupled magnetically, and that is rotated relative to the stator inside the stator; and a pair of magnetic field coils that are disposed radially inside the rotor magnetic poles, and that generate magnetic flux inside the stator and inside the rotor, wherein the rotor includes: a pair of first and second magnetic end plates that are disposed so as to be separated from each other in an axial direction; a magnetic intermediate plate that is disposed between the pair of magnetic end plates in the axial direction, and that is also disposed between the pair of field coils in the axial direction; a plurality of first magnetic pole members that extend axially, and that are disposed so as to be spaced apart circumferentially from each other such that first end portions and second end portions are respectively coupled magnetically and mechanically to the first magnetic end plate and to the second magnetic end plate and so as to be separated from the magnetic intermediate plate magnetically; a plurality of second magnetic pole members that extend axially, that are disposed so as to be spaced apart circumferentially from each other such that intermediate portions are coupled magnetically and mechanically to the magnetic intermediate plate and so as to be separated from each of the magnetic end plates magnetically, that are respectively inserted between the first magnetic pole members, and that constitute the rotor magnetic poles together with the first magnetic pole members; a plurality of permanent magnets that are respectively disposed between the first magnetic pole members and the second magnetic pole members in a circumferential direction such that first end portions extend to the first magnetic end plate and second end portions extend to the second magnetic end plate; and a nonmagnetic holding body for separating the first magnetic pole members magnetically from the magnetic intermediate plate, and for separating the second magnetic pole members magnetically from the magnetic end plates.
According to the present invention, a Lundell rotary machine that enables increases in efficiency and increases in output can be achieved by disposing the permanent magnets along almost an entire length of the rotor.
Preferred embodiments of the present invention will now be explained.
A Lundell rotary machine according to Embodiment 1 of the present invention is shown in
The Lundell rotary machine includes: a tubular stator 1; a rotor 2 that is supported so as to be coaxial to the stator 1 so as to be rotatable inside the stator 1; and a pair of magnetic field coils 3 that are disposed inside the rotor 2, and that generate magnetic flux inside the stator 1 and inside the rotor 2.
The stator 1 has: a hollow cylindrical frame body 4; a stator core 6 that has a plurality of stator magnetic poles 5 that are disposed so as to be spaced apart circumferentially, and that is fixed to an inner circumferential surface of a cylindrical portion of the frame body 4; and a stator coil 7 that is wound onto the plurality of stator magnetic poles 5.
The rotor 2 has: a rotating shaft 9 that is supported by bearings 8 so as to be coaxial to the stator 1 so as to be rotatable relative to the stator 1; a rotor core 11 that has a plurality of rotor magnetic poles 10 that are disposed so as to be spaced apart circumferentially, that is fixed to the rotating shaft 9 by shrinkage fitting, etc., and that rotates relative to the stator 1 inside the stator 1 together with the rotating shaft 9; and a plurality of permanent magnets 12 that are disposed between the plurality of rotor magnetic poles 10 so as to change magnetic pole direction alternately, and that are magnetized circumferentially so as to reduce the magnetic flux leakage between the rotor magnetic poles 10.
The magnetic flux of the permanent magnets 12 is configured so as to interlink with the stator magnetic poles 5. If the permanent magnets 12 are produced using rare earth bonded magnets that are formed using sintered ferrite or an insulating body, eddy currents are not generated in the magnet portions, eliminating wasteful loss, and enabling increases in efficiency. The rotor magnetic poles 10 are disposed so as to be spaced apart from each other circumferentially so as to face the stator magnetic poles 5 radially, being set so as to be able to be coupled to the stator magnetic poles 5 magnetically via an air gap.
The rotor core 11 has: a pair of (first and second) magnetic end plates 21 that are fixed to the rotating shaft 9 so as to be disposed so as to be separated from each other in an axial direction of the rotor 2 (hereinafter simply “the axial direction”); a magnetic intermediate plate 23 that is fixed to the rotating shaft 9 so as to be disposed between the pair of magnetic end plates 21 in the axial direction; a plurality of first magnetic pole members 24 that extend axially, and that are disposed so as to be spaced apart circumferentially from each other such that first end portions and second end portions are respectively coupled magnetically and mechanically to the first magnetic end plate 21 and to the second magnetic end plate 21, and so as to be separated from the magnetic intermediate plate 23 magnetically; a plurality of second magnetic pole members 25 that extend axially, that are disposed so as to be spaced apart circumferentially from each other such that intermediate portions are coupled magnetically and mechanically to the magnetic intermediate plate 23 and so as to be separated from each of the magnetic end plates 21 magnetically, that are respectively inserted between the first magnetic pole members 24, and that constitute the above-mentioned rotor magnetic poles 10 together with the first magnetic pole members 24; and a nonmagnetic holding body 26 that supports the first magnetic pole members 24 and the second magnetic pole members 25 along almost an entire length thereof, for separating the first magnetic pole members 24 magnetically from the magnetic intermediate plate 23, and for separating the second magnetic pole members 25 magnetically from each of the magnetic end plates 21.
Consequently, the configuration of the rotor core 11 is a tandem configuration in which a Lundell magnetic core portion in which the first and second magnetic pole members 24 and 25 are assembled in the holding body 26 so as to extend from opposite axial ends to each other and intermesh with each other circumferentially between the first magnetic end plate 21 and the magnetic intermediate plate 23, and a Lundell magnetic core portion in which the first and second magnetic pole members 24 and 25 are assembled so as to extend from opposite axial ends to each other and intermesh with each other circumferentially between the second magnetic end plate 21 and the magnetic intermediate plate 23, are coupled in the axial direction.
The rotating shaft 9 has: a cylindrical rotating shaft main body 100 that passes through the rotor core 11 in the axial direction; and a pair of internal magnetic members 101 that are fixed to the rotating shaft main body 100, and that are respectively disposed between each of the pair of magnetic end plates 21 and the magnetic intermediate plate 23 in the axial direction. The shape of each of the internal magnetic members 101 is a cylindrical shape into which the rotating shaft main body 100 fits radially inside.
Each of the field coils 3 is disposed radially further inward than each of the first magnetic pole members 24 and each of the second magnetic pole members 25 (i.e., the rotor magnetic poles 10), and is disposed radially further outward than each of the internal magnetic members 101. The pair of magnetic field coils 3 are disposed so as to line up in the axial direction between the pair of magnetic end plates 21. In addition, the magnetic intermediate plate 23 is disposed between the pair of magnetic field coils 3. Each of the field coils 3 is fixed to the rotor core 11 so as to be rotated together with the rotor 2. An electric current is supplied to each of the field coils 3 from outside by means of slip rings (not shown) that are disposed on the rotating shaft 9 so as to be positioned closer to an axial end portion than the rotor core 11.
The magnetic intermediate plate 23 is disposed at a central position between the pair of magnetic end plates 21 in the axial direction. The rotor 2 has a symmetrical configuration relative to a plane that passes through a center of the magnetic intermediate plate 23 perpendicular to the shaft axis of the rotor 2.
Each of the magnetic end plates 21, the magnetic intermediate plate 23, each of the first magnetic pole members 24, and each of the second magnetic pole members 25 are respectively constituted by a laminated body in which a plurality of magnetic sheets are laminated in the axial direction. In the depicted example, each of the magnetic end plates 21, the magnetic intermediate plate 23, each of the first magnetic pole members 24, and each of the second magnetic pole members 25 are assembled and held firmly together with the permanent magnets 12 by being held by the holding body 26 and fastening bolts 13 that constitute fastening means that pass through and fasten them. Each of the magnetic end plates 21 and the magnetic intermediate plate 23 are fixed firmly onto the rotating shaft 9 by fitting inner circumferential edges thereof onto the rotating shaft 9.
The holding body 26 has: a cylindrical nonmagnetic member 31 that is disposed between the magnetic end plates 21 and the magnetic intermediate plate 23 in the axial direction, and that supports each of the first magnetic pole members 24 and the second magnetic pole members 25 on a radially inner side; a plurality of nonmagnetic members 32 that are interposed between the magnetic intermediate plate 23 and the first magnetic pole members 24 radially; a nonmagnetic member 33 that is interposed between the magnetic intermediate plate 23 and the first magnetic pole members 24, and that fills a space between the nonmagnetic member 31 and the nonmagnetic members 32; a plurality of nonmagnetic members 34 that are interposed between the magnetic end plates 21 and the second magnetic pole members 25 radially; a nonmagnetic member 35 that is interposed between the magnetic end plates 21 and the second magnetic pole members 25, and that fills a space between the nonmagnetic member 31 and the nonmagnetic member 34; and a plurality of nonmagnetic members 36 that are disposed axially outside each of the second magnetic pole members 25. Each of the field coils 3 is disposed radially inside the cylindrical nonmagnetic member 31.
As shown in
As shown in
As shown in
As shown in
As shown in
As shown in
Flow of magnetic flux that is generated by passage of the electric current to the field coils 3 will now be explained.
Each of the first magnetic pole members 24 and the magnetic intermediate plate 23 are respectively separated magnetically by each of the nonmagnetic members 32 and 33. Each of the second magnetic pole members 25 and each of the magnetic end plates 21 are respectively separated magnetically by each of the nonmagnetic members 34 through 36. The magnetic flux is thereby less likely to leak inside the rotor 2.
As described above, the first magnetic pole members 24 and the second magnetic pole members 25 are supported radially and circumferentially by engagement between the respective dovetails 42 of the first magnetic pole members 24 and the second magnetic pole members 25 and the dovetail grooves 41 of the holding body 26, and in addition to radially and circumferentially, are also supported in the axial direction by fastening using the fastening bolts 13.
In
Eave portions 27 that engage the permanent magnets 12 radially are formed on radially outer corner portions of the first magnetic pole members 24 and the second magnetic pole members 25. By being engaged by the eave portions 27, the permanent magnets 12 are prevented from disengaging radially outward from between the first magnetic pole members 24 and the second magnetic pole members 25. The permanent magnets 12 are thereby supported firmly in the rotor core 11 so as to be able to tolerate centrifugal forces due to the rotation of the rotor 2.
As shown in
Thus, the first magnetic pole members 24 and the second magnetic pole members 25 are supported by the holding body 26 by the dovetails 42 engaging with the dovetail grooves 41 that are formed axially on outer circumferential portions of each of the nonmagnetic members 31 through 35. The permanent magnets 12 are supported along almost an entire length of the rotor core 11 by the first magnetic pole members 24, the second magnetic pole members 25, and the holding body 26. In addition, an assemblage of this kind is collectively fastened by the fastening bolts 13 that pass through the rotor core 11. Consequently, sufficient mechanical strength can be achieved even if the rotor core 11 is an assemblage that has high overall rigidity, and axial dimensions thereof are large.
In a Lundell rotary machine of this kind, because the first magnetic pole members 24, which are connected to the pair of magnetic end plates 21 magnetically and mechanically, are separated magnetically from the magnetic intermediate plate 23, and the second magnetic pole members 25, which are connected to the magnetic intermediate plate 23 magnetically and mechanically, are separated magnetically from the pair of magnetic end plates 21, and the permanent magnets 12 are disposed between the first magnetic pole members 24 and the second magnetic pole members 25 circumferentially, and first end portions of the permanent magnets 12 extend to the first magnetic end plate 21, and second end portions extend to the second magnetic end plate 21, the permanent magnets 12 can be disposed along almost the entire length of the rotor core 11 from a position of the first magnetic end plate 21, through a position of the magnetic intermediate plate 23, to a position of the second magnetic end plate 21. The magnetic flux of the permanent magnets 12 can thereby be made to interlink with the stator magnetic poles 5 along almost the entire length of the rotor core 11, enabling the stator 1 to be used effectively. Increased efficiency can thereby be achieved in the Lundell rotary machine. Furthermore, because the permanent magnets 12 are also disposed at the position of the magnetic intermediate plate 23 in the axial direction, not only alleviation of magnetic saturation of both the first magnetic pole members 24 and the second magnetic pole members 25, but also alleviation of magnetic saturation of the magnetic intermediate plate 23 can be achieved, enabling increased output to be achieved in the Lundell rotary machine.
Now,
As shown in
Because the rotor core 11 is configured using laminated bodies of magnetic sheets, the occurrence of eddy currents due to fluctuations in the magnetic flux that passes through the rotor core 11 can be suppressed, enabling eddy current loss that arises in the rotor core 11 to be suppressed. Increased efficiency can thereby be further achieved in the Lundell rotary machine.
Because the permanent magnets 12 are supported in a state of contact with the respective first magnetic pole members 24 and second magnetic pole members 25, the magnetic gap is reduced enabling magnetic saturation alleviating effects from the magnets to be increased even using comparatively less expensive ferrite magnets, and since declines in output due magnetic saturation of the rotor 2 are reduced as a result thereof even if large field magnetomotive forces are applied to the field coil 3, the magnetic flux of the permanent magnets 12 can be used effectively, enabling a high-torque motor (rotary machine) to be achieved.
Because the first magnetic pole members 24 and the second magnetic pole members 25 are all supported by the dovetail grooves 41 that are disposed on the holding body 26, and the permanent magnets 12 are supported by the first magnetic pole members 24 and the second magnetic pole members 25, the mechanical strength of the rotor 2 can be increased. Furthermore, because the permanent magnets 12 are not supported by separate special mechanisms that are prepared anew, but rather are supported by components that are necessary for the configuration of the rotor core 11, the need for production of new parts for the Lundell rotary machine is eliminated, enabling reduced costs and superior mass producibility.
In Embodiment 1, the respective cross-sectional shapes of the first magnetic pole members 24 and the second magnetic pole members 25 are mutually different than each other at axial end portions and axially intermediate portions, but the respective cross-sectional shapes of the first magnetic pole members 24 and the second magnetic pole members 25 may be identically shaped over an entire axial length.
Specifically,
Each of the nonmagnetic members 61 and the nonmagnetic member 31 line up in the axial direction such that radially outer portions connect with each other without differences in level. Dovetails 42 that engage with dovetail grooves 41 of the magnetic intermediate plate 23 are disposed on radially inner portions of the nonmagnetic member 61, and dovetail grooves 41 with which dovetails 42 of the first magnetic pole members 24 engage are disposed on radially outer portions of the nonmagnetic member 61. The nonmagnetic member 61 is fixed radially and circumferentially onto the magnetic intermediate plate 23 by engagement of the dovetails 42 of the nonmagnetic member 61 into the dovetail grooves 41 of the magnetic intermediate plate 23, and the first magnetic pole members 24 are fixed radially and circumferentially onto the nonmagnetic member 61 by engagement of the dovetails 42 of the first magnetic pole members 24 into the dovetail grooves 41 of the nonmagnetic member 61.
Each of the nonmagnetic members 62 and the nonmagnetic member 31 line up in the axial direction such that radially outer portions connect with each other without differences in level. Dovetails 42 that engage with dovetail grooves 41 of the magnetic end plates 21 are disposed on radially inner portions of the nonmagnetic member 62, and dovetail grooves 41 with which dovetails 42 of the second magnetic pole members 25 engage are disposed on radially outer portions of the nonmagnetic member 62. The nonmagnetic members 62 are fixed radially and circumferentially onto the magnetic end plates 21 by engagement of the dovetails 42 of the nonmagnetic members 62 into the dovetail grooves 41 of the magnetic end plates 21, and the second magnetic pole members 25 are fixed radially and circumferentially onto the nonmagnetic members 62 by engagement of the dovetails 42 of the second magnetic pole members 25 into the dovetail grooves 41 of the nonmagnetic members 62.
A cross-sectional shape of the first magnetic pole members 24 is an identical shape along an entire axial length. A cross-sectional shape of the second magnetic pole members 25 is also an identical shape along an entire axial length. The rest of the configuration is similar or identical to that of Embodiment 1. It has been confirmed that output torque from a Lundell rotary machine according to Embodiment 2 is also improved in a similar manner to that of Embodiment 1.
In a Lundell rotary machine of this kind, because the respective cross-sectional shapes of the first magnetic pole members 24 and the second magnetic pole members 25 are an identical shape along an entire axial length, a nonmagnetic member 33 for filling differences in level between a nonmagnetic member 31 and a nonmagnetic member 32 can be eliminated, for example, enabling the number of parts that constitute the holding body 26 to be reduced. Cost reductions can thereby be achieved. Production of the first magnetic pole members 24 and the second magnetic pole members 25 can also be facilitated.
Among a plurality of bolt passage apertures 43 that are disposed on a magnetic intermediate plate 23, at least one is an enlarged passage aperture 43a that is enlarged compared to the other bolt passage apertures 43, as shown in
Among a plurality of bolt passage apertures 43 that are disposed on a nonmagnetic member 33, at least one is an open aperture 43b that opens radially inward, as shown in
Among a plurality of bolt passage apertures 43 that are disposed on a first magnetic end plate 21 that is close to slip rings, at least one is an enlarged passage aperture 43c that is enlarged compared to the other bolt passage apertures 43, as shown in
Coil lead wires (not shown) that electrically connect slip rings and field coils 3, for supplying electric power to the field coils 3, are passed through each of the enlarged passage apertures 43a and 43c and the open apertures 43b together with fastening bolts 13. The coil lead wires from each of the field coils 3 are thereby connected to the common slip rings. In other words, it is possible for electric power supply to both of the field coils 3 to be performed from one direction only.
Now, in the above example, the bolt passage apertures 43 that are close to the first magnetic pole members 24 are made into the enlarged passage apertures 43a. The bolt passage apertures 43 that are close to the second magnetic pole members 25 may be made into enlarged passage apertures, but since bolt passage apertures 43 that are disposed on thin portions of the nonmagnetic member 33 become open apertures if the bolt passage apertures 43 that are close to the second magnetic pole members 25 are made into enlarged passage apertures, it is desirable for the bolt passage apertures 43 that are close to the first magnetic pole members 24 to be made into the enlarged passage apertures 43a.
Moreover, in the above example, the number of enlarged passage apertures 43a, enlarged passage apertures 43c, and open apertures 43b is two each, but the number of enlarged passage apertures 43a, enlarged passage apertures 43c, and open apertures 43b may be one, or may be three or more.
In the above example, the enlarged passage apertures 43a and 43c and the open apertures 43b through which the coil lead wires and the fastening bolts 13 are passed together are formed by enlarging the bolt passage apertures 43, but coil wire passage apertures that allow passage of the coil lead wires may be formed separately from the bolt passage apertures 43 on each of the magnetic intermediate plate 23, the magnetic end plates 21, and the nonmagnetic member 33.
Moreover, in the above example, the magnetic intermediate plate 23 and the magnetic end plates 21 are fixed onto the rotating shaft 9 by inserting the keys into the key insertion apertures, but are not limited thereto, and the magnetic intermediate plate 23 and the magnetic end plates 21 may be fixed onto the rotating shaft 9 by press-fitting or shrinkage fitting, for example.
As shown in
As shown in
In addition, as shown in
Moreover, the Lundell rotary machines that are explained above by way of illustration are embodiments that are shown simply as examples, and when implementing the present invention, many kinds of variations are possible, and features of the respective specific examples can be used wholly or selectively in combination with each other.
1 STATOR, 2 ROTOR, 3 FIELD COIL, 5 STATOR MAGNETIC POLE, 10 ROTOR MAGNETIC POLE, 12 PERMANENT MAGNET, 21 MAGNETIC END PLATE, 23 MAGNETIC INTERMEDIATE PLATE, 24 FIRST MAGNETIC POLE MEMBER, 25 SECOND MAGNETIC POLE MEMBER, 26 HOLDING BODY, 41 DOVETAIL GROOVE.
Kuroda, Yoichi, Inoue, Masaya, Morita, Masao, Shinkawa, Kanji, Hazeyama, Moriyuki
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